Population-based estimates of age-specific cumulative risk of breast cancer for pathogenic variants in ATM

Background Multigene panel tests for breast cancer predisposition routinely include ATM as it is now a well-established breast cancer predisposition gene. Methods We included ATM in a multigene panel test applied to the Australian Breast Cancer Family Registry (ABCFR), a population-based case–control–family study of breast cancer, with the purpose of estimating the prevalence and penetrance of heterozygous ATM pathogenic variants from the family data, using segregation analysis. Results The estimated breast cancer hazard ratio for carriers of pathogenic ATM variants in the ABCFR was 1.32 (95% confidence interval 0.45–3.87; P = 0.6). The estimated cumulative risk of breast cancer to age 80 years for heterozygous ATM pathogenic variant carriers was estimated to be 13% (95% CI 4.6–30). Conclusions Although ATM has been definitively identified as a breast cancer predisposition gene, further evidence, such as variant-specific penetrance estimates, are needed to inform risk management strategies for carriers of pathogenic variants to increase the clinical utility of population testing of this gene. Supplementary Information The online version contains supplementary material available at 10.1186/s13058-022-01518-y.


Background
Ataxia-Telangiectasia Mutated (ATM) encodes a protein kinase involved in DNA damage repair. Bi-allelic pathogenic variants in ATM cause Ataxia-Telangiectasia (A-T), a complex phenotype with poor prognosis. Heterozygous carriers do not display the clinical features of A-T except for an increased predisposition to various cancers, including breast cancer. Women who meet genetic testing criteria due to a personal or family history of breast cancer and are heterozygous carriers of a pathogenic variant in ATM have been estimated to be at a two-fourfold increase in breast cancer risk compared to non-carriers [1,2]. Several studies have reported breast cancer risk associated with carrying one missense pathogenic variant in ATM (c.7271T>G) to be high, setting it apart from other pathogenic variants in ATM in terms of the magnitude of associated breast cancer risk (e.g., OR 11.0 (1.42-85.7) p = 0.0019 [3]). Previously, using a population-based family study, we estimated the penetrance of ATM c.7271T>G to be 52% (95% CI 28-80%; HR = 8.6; 95% CI 3.9-18.9; P < 0.0001) [4]. Goldgar et al. estimated penetrance of likely pathogenic variants in ATM using data from 27 families (15 of which carried c.7271T > G) to be 60% to age 80 years [5].
Two recent large-scale, landmark studies have provided more insight into the prevalence of ATM pathogenic variants in population settings [6,7]. In these studies, 0.6-0.7% of affected women who did not carry a pathogenic Open Access and, by combining this OR with the SEER breast cancer incidence rates for the population, derived an estimate of lifetime absolute risk of breast cancer greater than 20% for ATM pathogenic variant carriers. These studies have clearly established the relative risk of breast cancer associated with ATM pathogenic variants for women in the general population. However, for the purposes of genetic counselling, estimates of age-specific cumulative risks (penetrance) are more clinically useful yet are limited for ATM pathogenic variants.
We conducted a genetic screen of ATM in the Australian Breast Cancer Family Registry (ABCFR), an Australian population-based case-control-family study of breast cancer, with the purpose of estimating the prevalence and penetrance of ATM pathogenic variants in this cohort.

Study participants and genomic data generation
The ABCFR is a population based, case-control-family study of breast cancer, carried out in Australia (Melbourne and Sydney) as part of the international Breast Cancer Family Registry (BCFR). Case-probands were over-sampled for those with early-onset breast cancer, but were sampled irrespective of family history. Bloodderived germline DNA from 1480 case probands and 864 control probands were screened by targeted-sequencing of the coding regions and proximal intron-exon junctions of BRCA1 (NM_007294.4), BRCA2 (NM_000059.4) and ATM (NM_000051.4). Details of study participant characteristics and selection, sequencing and data processing and variant filtering and annotation methods have been published previously [8] and are summarized in Additional file 1: Fig. S1.

Genetic variant selection
Our statistical analyses focused on rare pathogenic or predicted deleterious variants, hereafter refer to as "pathogenic". Rare variants were defined as those identified in the non-Finnish European population of gno-mAD [9] and in the ABCFR with a minor allele frequency (MAF) ≤ 0.001. To define pathogenic variants, ClinVar annotations of "Pathogenic" or "Likely Pathogenic" were used (accessed July 2021). Predicted deleterious variants included truncating variants that were not present in ClinVar and a subset of missense substitutions as described below.
For ATM, the specific domains in which missense substitutions have been more commonly associated with A-T are the FAT, kinase and FATC domains. Therefore, missense substitutions were scored using the web version of Align-GVGD [10], and our statistical analysis included missense substitutions that i) fell into the PFAM FAT (residues 2096-2849), PPI3_PI4_kinase (residues 2713-2962) and FATC (residues 3025-3056) domain definitions and ii) received an Align-GVGD grade of C55 or C65, indicating that they were evolutionary unlikely (deleterious).

Statistical analyses
Hazard ratios (HRs) and age-specific cumulative risks (penetrance) were estimated as described in detail in [8]. Briefly, HRs for carriers of pathogenic ATM variants were estimated by segregation analysis as implemented in the statistical package MENDEL version 3.2, then the estimated cumulative risk to a given age was derived from the estimated HR. All estimates were appropriately adjusted for the population-based ascertainment of the families, and an unmeasured polygene was used to model any residual familial aggregation of breast cancer. Non-carrier incidences were chosen so that the average incidence for carriers and non-carriers (weighted by the carrier frequency) was the age-specific population incidence rates for Australia in the period 1998-2002, as obtained from Cancer Incidence in Five Continents [11]. The population cumulative risk to age 80 was taken to be 10.9%. The allele frequency of all pathogenic ATM variants combined was taken to be 0.001. All p values were 2-sided, and a p value threshold of 0.05 was used to define statistical significance.
The risk estimates were based on 1029 relatives of the 34 probands who carried a pathogenic ATM variant. Of these relatives, 33 had germline DNA for testing, and 19 were female breast cancer cases. In addition, a number of relatives had cancers of other anatomical sites (though only breast cancer contributed to our analyses): 20 lung, 20 prostate, 12 colorectum, 8 stomach and 56 at other anatomical sites (none reported more than five times). The relatives included 17 known carriers and 16 known non-carriers of the pathogenic ATM variant identified in the proband, though ungenotyped people also contributed to our estimates via their phenotypes and their relationships to genotyped people.
The estimated breast cancer HR for carriers of pathogenic ATM variants in the ABCFR was 1.32 (95% CI 0.45-3.87; P = 0.6). Excluding the rare missense variants that are predicted to be deleterious but do not yet have a ClinVar classification (Additional Table 1) did not change the HR for carriers (1.36 (95% CI 0.44-4.16; P = 0.6). Based on the above HR estimate for all pathogenic ATM

Discussion
Variant classification remains a critical challenge to fully realize the clinical utility of genetic testing for ATM. This important issue and others have been identified as areas of priority by the International Consortium on ATM and Cancer, initiated in 2019, which brings together researchers and clinicians who aim to use a collaborative, multidisciplinary approach to addressing key questions about the cancer risks for carriers of a pathogenic ATM variant [12].
For ATM, as is the case for most breast cancer predisposition genes, truncating variants are, with a few exceptions, predicted to lead to loss of protein function and are classified as pathogenic. However, focusing on the FAT, kinase and FATC domains in ATM, Tavtigian et al. reported that the risk associated with carrying missense variants identified in these three domains (in aggregate) could be higher than that of protein truncating variants (in aggregate) [13]. Only a handful of ATM missense variants have been reported to be pathogenic in ClinVar. Missense variants represent a large proportion of the rare variants identified in our study: 70/129 (54%) of all rare variants in our study were missense substitutions but only 3/70 are classified as pathogenic in ClinVar.
We previously calculated cumulative risk estimates for CHEK2 in the ABCFR and observed that the penetrance estimates for pathogenic variants in CHEK2 and ATM are not statistically different (Fig. 1)  as ATM and CHEK2, as these genes are now routinely included on gene panels for cancer predisposition. While these two genes are considered bona fide breast cancer predisposition genes, national best practice recommendations are only emerging to guide the management of women found to carry pathogenic variants in these genes. This situation results in a feeling of uncertainty and anxiety in these women [14].

Conclusion
Further international collaboration is required, potentially via the newly formed International Consortium on ATM and Cancer [12], to refine the penetrance estimates, identify relevant modifying factors (including the polygenic risk score), and the risk of other cancers for carriers of ATM pathogenic variant carriers.